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Test-Time Regret Minimization in Meta Reinforcement Learning

Machine Learning 2024-06-05 v1

Abstract

Meta reinforcement learning sets a distribution over a set of tasks on which the agent can train at will, then is asked to learn an optimal policy for any test task efficiently. In this paper, we consider a finite set of tasks modeled through Markov decision processes with various dynamics. We assume to have endured a long training phase, from which the set of tasks is perfectly recovered, and we focus on regret minimization against the optimal policy in the unknown test task. Under a separation condition that states the existence of a state-action pair revealing a task against another, Chen et al. (2022) show that O(M2log(H))O(M^2 \log(H)) regret can be achieved, where M,HM, H are the number of tasks in the set and test episodes, respectively. In our first contribution, we demonstrate that the latter rate is nearly optimal by developing a novel lower bound for test-time regret minimization under separation, showing that a linear dependence with MM is unavoidable. Then, we present a family of stronger yet reasonable assumptions beyond separation, which we call strong identifiability, enabling algorithms achieving fast rates log(H)\log (H) and sublinear dependence with MM simultaneously. Our paper provides a new understanding of the statistical barriers of test-time regret minimization and when fast rates can be achieved.

Keywords

Cite

@article{arxiv.2406.02282,
  title  = {Test-Time Regret Minimization in Meta Reinforcement Learning},
  author = {Mirco Mutti and Aviv Tamar},
  journal= {arXiv preprint arXiv:2406.02282},
  year   = {2024}
}
R2 v1 2026-06-28T16:52:54.149Z